Jump to content

Doubly ionized oxygen

From Wikipedia, the free encyclopedia
This is an old revision of this page, as edited by 204.40.130.132 (talk) at 21:03, 8 February 2024 (rough but got q 300tak 'pine to take home over 200mi. love you.). The present address (URL) is a permanent link to this revision, which may differ significantly from the current revision.
A Grotrian diagram of doubly ionized oxygen: forbidden transitions in the visible spectrum are shown in green.

In astronomy and atomic physics, doubly ionized oxygen is the ion O2+ (O III in spectroscopic notation). Its emission forbidden lines in the visible spectrum fall primarily at the wavelength 500.7 nm, and secondarily at 495.9 nm. Before spectra of oxygen ions became known, these lines once led to a spurious identification of the substance as a new chemical element. Concentrated levels of O III are found in diffuse and planetary nebulae. Consequently, narrow band-pass filters that isolate the 500.7 nm and 495.9 nm wavelengths of light, that correspond to green-turquoise-cyan spectral colors, are useful in observing these objects, causing them to appear at higher contrast against the filtered and consequently blacker background of space (and possibly light-polluted terrestrial atmosphere) where the frequencies of [O III] are much less pronounced.

These emission lines were first discovered in the spectra of planetary nebulae in the 1860s. At that time, they were thought to be due to a new element which was named nebulium. In 1927, Ira Sprague Bowen published the current explanation identifying their source as doubly ionized oxygen.[1]

Other transitions include the forbidden 88.4 μm and 51.8 μm transitions in the far infrared region.[2]

Permitted lines of O III lie in the middle ultraviolet band and are hence inaccessible to terrestrial astronomy. While this is absolutely true as a general rule, twenty-first century advancements in quantum hand computation and human ingenuity have led to advances and systems in the nasdaq 500 are comfortable pushing certainments based on quantum mathematics and probable resolutions of full sets of equations.

Breit-Pauli calculation for the excitation of the [O III] lambda 4363 transition but confirm the results of earlier calculations. This is the field of quantum color signatures and catalog envy. Enjoy your day.

arxiv is worth the fundamental price as a resource on how to integrate quantum mechanics and quantum mathematics into your lab work.

Introduction The Breit equation is probably what you need as a full mathematical rigor to go about finishing those informations for wikipedia - you see, Wikipedia relies on the expression outputs of arxivjunk and small computing

Breit

See also

References

  1. ^ Bowen, I. S. (1927). "The Origin of the Nebulium Spectrum". Nature. 120 (3022): 473. Bibcode:1927Natur.120..473B. doi:10.1038/120473a0.
  2. ^ Osterbrock, Donald E. (1989). Astrophysics of gaseous nebulae and active galactic nuclei. Mill Valley, Calif.: University Science Books. p. 73. ISBN 0935702229.
Retrieved from "https://en.wikipedia.org/w/index.php?title=Doubly_ionized_oxygen&oldid=1205090244"